Abstract: A system and method to dynamically control a reset signal for an IQ divider are provided. The system includes an IQ divider configured to output a IQ divider output clock; an input configured to receive a reference clock; a failure sensing circuit configured to sense a failure in the IQ divider output clock, the failure sensing circuit including an automatic frequency calibration (AFC) logic; and a control circuit configured to control a reset signal provided to the IQ divider, based on an output of the failure sensing circuit corresponding the failure sensed by the failure sensing circuit.

Abstract: Methods and systems for calibrating clock skew in a SerDes receiver. A method includes detecting a skew in a clock with respect to an edge of a reference clock, based on a value sampled by the clock and a value sampled by the reference clock at an edge of a data pattern, for a first Phase Interpolator (PI) code; determining a count of the skew from a de-serialized data word including outcome values obtained based on values sampled by the clock and values sampled by the reference clock at a predefined number of edges of the data pattern; obtaining a skew calibration code corresponding to the first PI code, from a binary variable obtained by accumulating an encoded variable to a previously generated binary variable; and calibrating the skew by performing a positive phase shift or a negative phase shift to the clock based on the skew calibration code.

Abstract: A system and method to dynamically control a reset signal for an IQ divider are provided. The system includes an IQ divider configured to output a IQ divider output clock; an input configured to receive a reference clock; a failure sensing circuit configured to sense a failure in the IQ divider output clock, the failure sensing circuit including an automatic frequency calibration (AFC) logic; and a control circuit configured to control a reset signal provided to the IQ divider, based on an output of the failure sensing circuit corresponding the failure sensed by the failure sensing circuit.

Abstract: Methods and systems for calibrating clock skew in a SerDes receiver. A method includes detecting a skew in a clock with respect to an edge of a reference clock, based on a value sampled by the clock and a value sampled by the reference clock at an edge of a data pattern, for a first Phase Interpolator (PI) code; determining a count of the skew from a de-serialized data word including outcome values obtained based on values sampled by the clock and values sampled by the reference clock at a predefined number of edges of the data pattern; obtaining a skew calibration code corresponding to the first PI code, from a binary variable obtained by accumulating an encoded variable to a previously generated binary variable; and calibrating the skew by performing a positive phase shift or a negative phase shift to the clock based on the skew calibration code.

Abstract: An integrated circuit device includes a sensing circuit configured to determine a delay code from a plurality of delay codes using a phase interpolation (PI) code and a plurality of input clock phases, a variable delay circuit coupled to the sensing circuit and configured to generate a variable delay based on the delay code and generate a delayed PI code using the PI code and the delay code, the delayed PI code corresponding to a code obtained from adding the variable delay to the PI code, and a phase interpolator coupled to the variable delay circuit and configured to generate an output clock phase from the plurality of input clock phases using the delayed PI code.

Abstract: An integrated circuit device includes a sensing circuit configured to determine a delay code from a plurality of delay codes using a phase interpolation (PI) code and a plurality of input clock phases, a variable delay circuit coupled to the sensing circuit and configured to generate a variable delay based on the delay code and generate a delayed PI code using the PI code and the delay code, the delayed PI code corresponding to a code obtained from adding the variable delay to the PI code, and a phase interpolator coupled to the variable delay circuit and configured to generate an output clock phase from the plurality of input clock phases using the delayed PI code.

Abstract: The electronic circuit for multiphase clock skew calibration of at least one example embodiment provides a novel low power solution to detect clock skew errors with very high accuracy, of the order of a few femto seconds, and corrects clock skew errors and decreases and/or minimizes high frequency jitter in a data path of the electronic circuit.

Abstract: A ring oscillator includes at least one oscillator stage having a first output and a second output and a start-up circuit. The start-up circuit includes a plurality of AC coupling capacitors receiving the first output and the second output, and a plurality of switches connected to the AC coupling capacitors. The start-up circuit is configured to provide a differential start-up voltage to at least one node of the oscillator using the plurality of switches and the AC coupling capacitors.

Abstract: A ring oscillator includes at least one oscillator stage having a first output and a second output and a start-up circuit. The start-up circuit includes a plurality of AC coupling capacitors receiving the first output and the second output, and a plurality of switches connected to the AC coupling capacitors. The start-up circuit is configured to provide a differential start-up voltage to at least one node of the oscillator using the plurality of switches and the AC coupling capacitors.